2.4.5 Induction Charging: An Object Can Become Charged by Grounding It
In Figure 2.8, we saw that a voltage was induced on the metal object when a charged object was brought nearby. In that situation, we can discharge the capacitor Cm by connecting a ground wire between the metal object and earth. The positive charges on the metal object flow to earth. The voltage Vm is then zero (Figure 2.9). Note that at the time of connection, an ESD occurs as the charge flows to earth. This is an important phenomenon in ESD control – an ESD occurs when two conductors at different voltages make contact, e.g. when grounding a conductor in the presence of an electrostatic field.
If the earth wire is then removed, the metal object remains at zero volts. However, it has a net negative charge Q, as the balancing positive charge Q has flowed away. The metal plate is now charged although the voltage on it is zero! If the charged field source object is then taken away, the voltage on the metal object rises to a negative voltage due to its negative charge.
This process is called charging by induction. It can happen in practice if an object, tool, device, or person becomes grounded temporarily when in an electrostatic field.
If a person or object can become charged and can act as a source of electrostatic field, then a nearby device can be subjected to that field. If the device is momentarily grounded, ESD occurs at that time, and it can become charged by induction. This can leave it in a charged state, at risk of ESD occurring on subsequent contact with another conductor at different voltage – grounded or not. If a grounded person moves to pick up a sensitive device within an electrostatic field, they may cause an ESD event when they touch the ESD‐sensitive device. Practical demonstrations of these processes are given in Section 12.7.10.
Figure 2.9 An earthed metal plate in an electric field becomes charged by grounding.
Figure 2.10 Faraday pail.
Induced voltage differences can also lead to breakdown over small gaps between nearby conductors in a field, if the voltage difference exceeds the gap breakdown voltage. This can also lead to ESD risks.
2.4.6 Faraday Pail and Shielding of Charges Within a Closed Object
If a charged object is placed within a closed hollow conducting object such as a box, then the field lines from the charge couple to the surrounding conductor (Figure 2.10). The net charge contained within the conducting box induces an equal net charge on the box.
This principle is used to measure electrostatic charge on items by placing the charged item in a container, which is known as a Faraday pail.
If the container is grounded, then the outside world is shielded from electrostatic fields arising from the charges. If it is not grounded, then it is itself a charged object and can be a source of ESD.
2.5 Electrostatic Discharges
Normally air is an excellent insulator. If, however, the electrostatic field strength exceeds about 3 MV m−1 (3 kV mm−1), the insulating properties of air breaks down and ESD occurs. A large amount of stored charge can be rapidly dissipated by this event. The discharge may be sudden, as in sparks, or it may be gradual as in corona discharge.
An understanding of ESD is important in understanding the characteristics of ESD sources.
2.5.1 ESD (Sparks) Between Conducting Objects
The spark discharge occurs between conducting electrodes that initially have a high voltage difference between them. Large energies (μJ to >1 J) may be dissipated in very short, or long, times (ns to >ms) depending on discharge circuit (including the load characteristics). Peak currents are typically greater than about 0.1 A and can exceed 100 A. The discharge waveform is highly dependent on the source and “load” circuit characteristics and can have unidirectional or oscillatory waveforms (see Section 2.7).
The energy E stored in a capacitor C charged to voltage V is easily calculated using this simple formula
In the absence of significant series resistance, it is often reasonable to assume that all this energy is transferred to the discharge.
The electrical breakdown field strength of about 3 MV m−1 is valid for normal air pressure and rather large distances (e.g. for a gap of 10 mm and large diameter or flat electrodes, the breakdown voltage would be about 30 kV). The relationship between breakdown field strength and air pressure is given by Paschen's law (Kuffel et al. 2005) and is nearly linear for larger gaps and uniform fields. At smaller gap distances d the breakdown voltage reaches a minimum (known as the Paschen minimum). As breakdown voltage Vb is also dependent on atmospheric pressure P, the Paschen curve is usually plotted as breakdown voltage against the product Pd (Figure 2.11). For air, according to Paschen's law, below about 350 V no breakdown occurs (minimum Pd 0.55 Torr cm, or 7 μm at 1 atm), and ESD can happen only with direct metal‐to‐metal contact. There is evidence that in practice discharges can occur through small gaps below the Paschen minimum voltage, possibly due to field emission (Wallash and Levitt 2003).
2.5.2 ESD from Insulating Surfaces
If a conductive electrode approaches a charged insulating surface, a “brush” discharge can occur. Several contributory discharges occur on the insulating surface, radiating from a central spark channel – the whole looks rather like an old‐fashioned twig brush.
Brush discharges are less well documented than spark discharges. They typically have a lower peak discharge current than sparks (0.01–10 A) and unidirectional waveforms with fast rise and quasi‐exponential decay (Figure 2.12) (Norberg et al. 1989; Norberg 1992; Norberg and Lundquist 1991; Smallwood 1999; Landers 2018). The power dissipation and energy of a brush discharge is not easy to calculate.
Figure 2.11 The relationship between breakdown voltage and spark gap Pd (Paschen curve).